Stereoscopic focus point adjustment

ABSTRACT

A method of adjusting depth in a stereoscopic video may include generating a left-eye viewing frame of a stereoscopic video. The left-eye viewing frame may include a plurality of left-eye viewing frame elements. The method may also include generating a right-eye viewing frame of the stereoscopic video. The right-eye viewing frame may correspond to the left-eye viewing frame and may include a plurality of right-eye viewing frame elements. Further, each right-eye viewing frame element may correspond to one of the left-eye viewing frame elements. The method may additionally include determining an offset between each right-eye viewing frame element and its corresponding left-eye viewing frame element. Further, the method may include applying a uniform summing factor to each offset to uniformly shift by substantially the same amount each right-eye viewing frame element with respect to its corresponding left-eye viewing frame element such that a perceived focus point is adjusted.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation of U.S. application Ser. No.14/301,140, filed Jun. 10, 2014 which is incorporated herein byreference.

FIELD

The present disclosure relates to stereoscopic focus point adjustment.

BACKGROUND

Three-dimensional (stereoscopic) imaging to produce three-dimensionalvideos (e.g., television, movies, etc.) has become increasingly popularin recent years. One reason for this is that there has been asignificant improvement in the camera and postproduction technologiesused to create three-dimensional video. Another reason thatthree-dimensional videos are becoming popular is that theentertainment-viewing public appears willing to pay a premium for thisspecial effect.

However, three-dimensional filming technologies are such that it issignificantly more expensive to film a video using three-dimensionaltechnology as compared to using two-dimensional (monoscopic) technology.In addition, there are millions of two-dimensional videos that havealready been produced but were not filmed using three-dimensionaltechnologies.

As such, many have been trying to convert two-dimensional videos intothree-dimensional videos. These methods to convert two-dimensionalvideos for three-dimensional viewing, however, may not work, areresource intensive, and/or do not produce acceptable results (e.g.,produce a cardboard cutout effect).

The subject matter claimed herein is not limited to embodiments thatsolve any disadvantages or that operate only in environments such asthose described above. Rather, this background is only provided toillustrate one example technology area where some embodiments describedherein may be practiced.

SUMMARY

According to an aspect of an embodiment, a method of adjusting depth ina stereoscopic video may include generating a left-eye viewing frame ofa stereoscopic video. The left-eye viewing frame may include a pluralityof left-eye viewing frame elements. The method may also includegenerating a right-eye viewing frame of the stereoscopic video. Theright-eye viewing frame may correspond to the left-eye viewing frame andmay include a plurality of right-eye viewing frame elements. Further,each right-eye viewing frame element may correspond to one of theleft-eye viewing frame elements. The method may additionally includedetermining an offset between each right-eye viewing frame element andits corresponding left-eye viewing frame element. Further, the methodmay include applying a uniform summing factor to each offset touniformly shift by substantially the same amount each right-eye viewingframe element with respect to its corresponding left-eye viewing frameelement such that a perceived focus point associated with thestereoscopic video is adjusted.

The object and advantages of the embodiments will be realized andachieved at least by the elements, features, and combinationsparticularly pointed out in the claims.

It is to be understood that both the foregoing general description andthe following detailed description are exemplary and explanatory and arenot restrictive of the invention, as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

Example embodiments will be described and explained with additionalspecificity and detail through the use of the accompanying drawings inwhich:

FIG. 1 illustrates an example system for generating a stereoscopic (3-D)video based on a monoscopic (2-D) video;

FIG. 2 illustrates an example block diagram depicting the generation ofmodified frames associated with a monoscopic video based on movement ofelements between different frames of a monoscopic video;

FIG. 3 illustrates an example block diagram depicting the generation ofmodified frames associated with a monoscopic video where one or more ofthe modified frames may be generated based on one or more inferredframes of a monoscopic video;

FIG. 4 illustrates an example block diagram depicting the generation ofa left-eye viewing frame and a right-eye viewing frame of a stereoscopicvideo based on a right-panning effect associated with a monoscopicvideo;

FIG. 5 illustrates an example block diagram depicting the generation ofa left-eye viewing frame and a right-eye viewing frame of a stereoscopicvideo based on a left-panning effect associated with a monoscopic video;

FIG. 6 illustrates an example block diagram depicting the generation ofa left-eye viewing frame and a right-eye viewing frame of a stereoscopicvideo based on a zooming-out camera effect associated with a monoscopicvideo;

FIG. 7 illustrates an example block diagram depicting the generation ofa left-eye viewing frame and a right-eye viewing frame of a stereoscopicvideo based on a zooming-in camera effect associated with a monoscopicvideo;

FIG. 8 illustrates example frames of a monoscopic video where the framesinclude a fastest-moving element, a slow-moving element, and a dominantelement;

FIG. 9 is a flowchart of an example method of determining the foregroundand/or background of a scene based on at least one of a fastest-movingelement, a slow-moving element, and a dominant element associated withthe scene;

FIG. 10 illustrates an example block diagram for generating a left-eyeviewing frame and a right-eye viewing frame of a stereoscopic video froma monoscopic video based on movement of the foreground and/or backgroundassociated with the monoscopic video;

FIG. 11 is a flowchart of an example method of converting a monoscopicvideo into a stereoscopic video based on a camera effect;

FIG. 12A illustrates an example setting that may be perceived by a lefteye and a right eye;

FIG. 12B depicts an example grid that illustrates example offsets thatmay be found between elements in a left-eye viewing frame and aright-eye viewing frame of a stereoscopic video associated with thesetting of FIG. 12A;

FIG. 12C depicts an example grid that illustrates the offsets of theelements of FIG. 12B with respect to their respective left-eye andright-eye viewing frames after applying a uniform multiplying factor tothe offsets of FIG. 12B;

FIG. 12D depicts an example grid that illustrates the offsets of theelements of FIG. 12B with respect to their respective left-eye andright-eye viewing frames after applying a uniform summing factor to theoffsets of FIG. 12B;

FIG. 13 is a flowchart of an example method of adjusting the depth of astereoscopic video; and

FIG. 14 is a flow chart of an example method of adjusting the focuspoint of a stereoscopic video, all arranged in accordance with at leastsome embodiments described herein.

DESCRIPTION OF EMBODIMENTS

Humans have a binocular vision system that uses two eyes spacedapproximately two and a half inches (approximately 6.5 centimeters)apart. Each eye sees the world from a slightly different perspective.The brain uses the difference in these perspectives to calculate orgauge distance. This binocular vision system is partly responsible forthe ability to determine with relatively good accuracy the distance ofan object. The relative distance of multiple objects in a field of viewmay also be determined with the help of binocular vision.

Three-dimensional (stereoscopic) imaging takes advantage of the depthperceived by binocular vision by presenting two images to a viewer whereone image is presented to one eye (e.g., the left eye) and the otherimage is presented to the other eye (e.g., the right eye). The imagespresented to the two eyes may include substantially the same elements,but the elements in the two images may be offset from each other tomimic the offsetting perspective that may be perceived by the viewer'seyes in everyday life. Therefore, the viewer may perceive depth in theelements depicted by the images.

Traditionally, three-dimensional videos have been made using two videosources (e.g., cameras) that are mounted side by side, about three toeight inches apart, to capture a setting as it may be perceived by thetwo different eyes. This distance is often referred to as the“interaxial” or “interocular distance.” Accordingly, the two videosources create two videos; one for the left eye and one for the righteye. The two videos may be put together as a stereoscopic (or “3-D”)video, where the right-eye video is presented to the viewer's right eyeand the left-eye video is presented to the viewer's left eye such thatthe viewer perceives the video in three dimensions. In contrast, inaccordance with some embodiments of the present disclosure, astereoscopic video may be derived from a video obtained by using asingle (monoscopic) video source. These videos derived from a monoscopicvideo source may be referred to as “2-D” or “monoscopic videos.”

The term “video” may refer to any motion-type picture and may include,by way of example and not limitation, movies, television shows, recordedevents (e.g., sporting events, concerts, etc.), home movies, Internetvideos, etc. A video is made up of a series of “frames” (referred to as“frames” or “video frames”) that each display an image of a setting thatmay include elements or objects (referred to generally as “elements”).Elements may be moving or may be stationary. For example, a frame may bean image of a landscape that may include elements such as mountains,hills, trees, animals, buildings, planes, trains, automobiles, etc.

According to some embodiments, the movement of elements between a firstframe of a monoscopic video with respect to a second frame of themonoscopic video (e.g., a subsequent frame or a previous frame of thefirst frame) may be used to generate one or more modified first framesthat may correspond with the first frame and may be used to generate thestereoscopic video. In some embodiments, the first and second frames maybe consecutive frames, and in other embodiments, one or moreintermediate frames may be included between the first and second frames.The first frame and the modified first frames may include substantiallythe same elements with one or more elements offset from each other inthe first frame and the modified first frames based on the movement ofelements between the first frame and the second frame. Additionally, themovement of elements may be used to analyze a camera effect (e.g., azooming effect, a panning effect, a rotating effect, and/or a stationaryeffect) with respect to the first frame and the second frame. In someembodiments, the modified first frames may be generated based on theanalyzed camera effect.

In some embodiments, a left-eye viewing frame, which may be configuredto be viewed by a viewer's left eye, may be generated based on thedetermined camera effect and at least one of the first frame and themodified first frames. Similarly, a right-eye viewing frame, which maybe configured to be viewed by a viewer's right eye, may also begenerated based on the determined camera effect and at least one of thefirst frame and the modified first frames. This process may be repeatedfor multiple frames of the monoscopic video to generate correspondingleft-eye and right-eye viewing frames of a stereoscopic video.Accordingly, in such embodiments, a stereoscopic video may be generatedfrom a monoscopic video based on the analyzed camera effect and movementbetween the first frame and the second frame associated therewith.

Additionally, in some embodiments, the generation of the left-eyeviewing frame and the right-eye viewing frame may be based on adetermination of movement of at least one of a foreground and abackground of a scene of the monoscopic video associated with the firstframe and the second frame. In these or other embodiments, theforeground and/or background may be determined based on a fastest-movingelement, a slow-moving element, and/or a dominant element included inthe scene associated with the first frame and the second frame.

Additionally, the amount of depth in the stereoscopic video may bemodified by adjusting the offset between elements included in theleft-eye viewing frame and the right-eye viewing frame. Further, theperception of which elements may be within the foreground or backgroundof a setting associated with the stereoscopic video may also be modifiedby adjusting the offset between elements.

The right-eye viewing frames and the left-eye viewing frames describedherein may also be referred to as “right-eye images” and “left-eyeimages,” respectively. Additionally, the right-eye viewing frames andthe left-eye viewing frames may be used to generate stereoscopic videosusing any suitable 3D format such as top/bottom, left/right, SENSIO®Hi-Fi 3D, Blu-ray® 3D, or any other applicable 3D format.

FIG. 1 illustrates an example system 100 for generating a stereoscopic(3-D) video 103 based on a monoscopic (2-D) video 101, according to someembodiments of the present disclosure. The system 100 may include athree-dimensional (stereoscopic) video generation module 104 (referredto hereinafter as “stereoscopic video module 104”). The stereoscopicvideo module 104 may include any suitable system, apparatus, or deviceconfigured to receive the monoscopic video 101 and convert themonoscopic video 101 into the stereoscopic video 103. For example, insome embodiments, the stereoscopic video module 104 may be software thatincludes computer-executable instructions configured to cause aprocessor to perform operations for converting the monoscopic video 101into the stereoscopic video 103.

The stereoscopic video module 104 may be configured to generate thestereoscopic video 103 based on the movement of one or more elementsbetween frames of the monoscopic video 101. In some embodiments, thestereoscopic video module 104 may generate modified frames based on themovement. The generation of the modified frames that may be performed bythe stereoscopic video module 104 is discussed in further detail belowwith respect to FIGS. 2 and 3. In some embodiments, the stereoscopicvideo module 104 may also be configured to analyze and determine acamera effect associated with the monoscopic video 101 based on themovement of elements between frames. In these embodiments, thestereoscopic video module 104 may be configured to generate the modifiedframes and the left-eye and right-eye viewing frames for thestereoscopic video 103 based on the determined camera effect and themovement associated therewith. Further, in some embodiments, thestereoscopic video module 104 may be configured to generate the modifiedframes and the left-eye and right-eye viewing frames based on adetermination of movement associated with the foreground and backgroundwithin a scene of the monoscopic video 101. The analysis of the cameraeffect and generation of the modified frames and the left-eye andright-eye viewing frames that may be performed by the stereoscopic videomodule 104 based on the analyzed camera effect is discussed in furtherdetail with respect to FIGS. 4-7 and 10.

In some embodiments, the stereoscopic video module 104 may also beconfigured to determine the foreground and/or background of a scene ofthe monoscopic video 101. In some of these embodiments, the stereoscopicvideo module 104 may be configured to determine the foreground and/orbackground based on a fastest-moving element, a slow-moving element,and/or a dominant element included in a scene of the monoscopic video101. The determination of the fastest-moving element, slow movingelement, and/or the dominant element is further detailed with respect toFIG. 8. The determination of the foreground and/or background that maybe performed by the stereoscopic video module 104 is explained infurther detail below with respect to FIG. 9.

Further, in some embodiments, the stereoscopic video module 104 may beconfigured to adjust the amount of depth perceived by a viewer watchingthe stereoscopic video 103 by adjusting the offset between elementsincluded in the left-eye and right-eye viewing frames. The modificationof depth perception that may be performed by the stereoscopic videomodule 104 is discussed in further detail below with respect to FIGS.12A-12C and 13. Additionally, in some embodiments, the stereoscopicvideo module 104 may also be configured to adjust a focus point of thestereoscopic video 103 such that the stereoscopic video module 104 maymodify the perception of which elements may be within the foreground orbackground of a setting as perceived by the viewer. The modification ofthe focus point that may be performed by the stereoscopic video module104 is discussed in further detail below with respect to FIGS. 12A, 12B,12D, and 14.

As mentioned above, the stereoscopic video module 104 may be configuredto generate modified frames that may be used for generating left- and/orright-eye viewing frames of the stereoscopic video 103 based on movementof one or more elements between frames. FIG. 2 illustrates an exampleblock diagram 200 depicting the generation of modified frames 202′ basedon movement of elements between different frames 202 of a monoscopicvideo 201, according to some embodiments of the present disclosure. Insome embodiments, and given as an example with respect to FIG. 2, themodified frames 202′ may be generated by a stereoscopic video module,such as the stereoscopic video module 104 described above with respectto FIG. 1. As depicted in FIG. 2, the monoscopic video 201 may besubstantially similar to the monoscopic video 101 described with respectto FIG. 1 and may include a series of frames 202 that may include imagesof one or more settings associated with the monoscopic video 201.According to some embodiments of the present disclosure, thestereoscopic video module may generate the modified frames 202′ based onhorizontal movement between the frames 202 of one or more elements (notexpressly illustrated) between the frames 202.

For example, an element in the frames 202 a and 202 b (where the frame202 b may be a subsequent frame with respect to the frame 202 a) mayhave a change in position between the frame 202 a and the frame 202 bsuch that the element may move horizontally from the left to the rightbetween frames 202 a and 202 b. Accordingly, the stereoscopic videomodule may generate the modified frame 202 a′ based on the horizontalmovement of the element between frames 202 a and 202 b such that theelement is offset to the right in the modified frame 202 a′ with respectto the frame 202 a. The stereoscopic video module may similarly generatethe modified frame 202 b′ based on frames 202 b and 202 c (where theframe 202 c may be a subsequent frame with respect to the frame 202 b),and the modified frame 202 c′ based on frames 202 c and 202 d (where theframe 202 d may be a subsequent frame with respect to the frame 202 c).Accordingly, the elements of the modified frames 202′ may behorizontally offset with respect to the corresponding elements of thecorresponding frames 202 based on horizontal movement of elementsbetween frames to mimic the horizontal offset of images as perceived bya viewer's right eye and left eye.

In some embodiments, the movement of an element between frames 202 mayalso be in a vertical direction (referred to as “vertical movement”).However, because a viewer's eyes are generally not substantially offsetin a vertical direction, the stereoscopic video module may substantiallyignore the vertical movement of elements between frames 202 whengenerating modified frames 202′. Therefore, modified frames 202′ may begenerated such that their elements are horizontally offset in modifiedframes 202′ with respect to the corresponding elements in theirassociated frame 202 based on the horizontal movement. However, theelements of the modified frames 202′ may not be vertically offset to asubstantial degree with respect to the corresponding elements of theirassociated frames 202 even if vertical movement occurs between frames.

Additionally, in some embodiments, the movement of elements from oneframe to another frame may result in one or more elements in a frame notbeing present in a subsequent frame that may be used to generate amodified frame. In such instances, the stereoscopic video module 104 maycopy the missing elements from the original frame and place them in theassociated modified frame.

For example, an element of the frame 202 a may be a hand of a person andmovement of the person between the frame 202 a and the frame 202 b maybe such that the hand of the person is not visible in the frame 202 b.Additionally, the modified frame 202 a′ may be generated based onhorizontal movement of the person from the frame 202 a to the frame 202b. Therefore, in generating the modified frame 202 a′ based on thehorizontal movement of the person, the person may be horizontally offsetin the modified frame 202 a′ based on the horizontal offset of theperson between frames 202 a and 202 b. However, the person's hand may becopied from the frame 202 a and inserted in the modified frame 202 a′.Consequently, the hand may be present in the modified frame 202 a′ eventhough the hand may be missing from the frame 202 b from which thehorizontal offset of the elements of the modified frame 202 a′ may bederived.

Modifications, additions, or omissions may be made to FIG. 2 withoutdeparting from the scope of the present disclosure. For example, themonoscopic video 201 may include more or fewer frames than thoseexplicitly illustrated. Further, in some embodiments, one or moreintermediate frames may be included between the frames illustrated. Forexample, the monoscopic video 201 may include one or more intermediateframes that may be between frames 202 a and 202 b, frames 202 b and 202c, and/or frames 202 c and 202 d. Additionally, in some embodiments, ascene within the monoscopic video 201 may change such that one frame 202may be associated with one scene and a subsequent frame may beassociated with a different scene. In the present disclosure, a “scene”may refer to a particular camera perspective or angle with respect to aparticular setting such that a “scene change” or change in a scene mayrefer to a change in a camera angle or perspective of the same settingand/or a change in setting depicted in a video. In such embodiments, amodified frame may be generated based on an inferred frame where theinferred frame may be based on movement of one or more elementsidentified in previous frames.

FIG. 3 illustrates an example block diagram 300 depicting the generationof modified frames 302′ where one or more modified frames 302′ may begenerated based on one or more inferred frames 305 of a monoscopic video301, according to some embodiments of the present disclosure. In someembodiments, and given as an example with respect to FIG. 3, themodified frames 302′ may be generated by a stereoscopic video modulesuch as the stereoscopic video module 104 described above with respectto FIG. 1. As depicted in FIG. 3, the monoscopic video 301 may include aseries of frames 302 (depicted as frames 302 a-302 d) that may includeimages of one or more scenes associated with the monoscopic video 301.In the illustrated embodiment, the frames 302 a-302 c may be associatedwith a scene 306 a of the monoscopic video 301 and the frame 302 d maybe associated with a different scene, a scene 306 b, of the monoscopicvideo 301.

According to some embodiments of the present disclosure, thestereoscopic video module may be configured to generate modified frames302 a′ and 302 b′ based on movement of one or more elements (notexpressly illustrated) between frames 302 a and 302 b, and 302 b and 302c, respectively, similarly to the generation of modified frames 202 a′and 202 b′ described above. For example, the modified frame 302 a′ maybe generated based on movement of one or more elements between the frame302 a and the frame 302 b (which may be a subsequent frame of frame 302a). Additionally, the modified frame 302 b′ may be generated based onmovement of one or more elements between the frame 302 b and the frame302 c (which may be a subsequent frame of frame 302 b).

However, in the illustrated embodiment, the frame 302 c may be the lastframe associated with the scene 306 a of the monoscopic video 301.Therefore, movement of an element associated with the frame 302 c maynot be present between the frame 302 c and subsequent frames of theframe 302 c because the subsequent frames, such as the frame 302 d, maybe associated with a different scene or may not have a substantialdegree of movement associated with them before transitioning to anotherframe. In instances such as this, the stereoscopic video module may beconfigured to generate an inferred frame that may represent a subsequentframe of the scene had the scene continued past its last frame. Forexample, in the illustrated embodiment, the stereoscopic video modulemay be configured to generate an inferred frame 305 that may represent asubsequent frame of the frame 302 c of the scene 306 a had the scene 306a continued past the frame 302 c, which in the illustrated embodimentmay be the last frame of the scene 306 a.

In some embodiments, the stereoscopic video module may be configured todetermine a scene change and may determine the last frame of a scenebased on the detected scene change. The stereoscopic video module mayalso be configured to generate the inferred frame based on detecting thescene change. For example, the stereoscopic video module may beconfigured to detect the scene change from the scene 306 a to the scene306 b, may determine that the frame 302 c is the last frame of the scene306 a, and may generate the inferred frame 305 based on detecting thescene change from the scene 306 a to the scene 306 b.

In some of these embodiments, the stereoscopic video module may beconfigured to determine the scene change based on an analysis of spatialand/or color distribution of pixels between frames. If the distributionof pixels is substantially similar from one frame to another, thestereoscopic video module may determine that the frames 302 areassociated with the same scene 306. However, if the distribution ofpixels between frames is substantially different, the stereoscopic videomodule may determine that a scene change has occurred. For example, thestereoscopic video module may determine that the distribution of pixelsbetween frames 302 a, 302 b, and 302 c is substantially similar todetermine that the frames 302 a, 302 b, and 302 c may be part of thescene 306 a. The stereoscopic video module may also determine that thedistribution of pixels between the frames 302 c and 302 d issubstantially different to determine that a scene change from the scene306 a to the scene 306 b occurs between the frames 302 c and 302 d.

In response to detecting a scene change from a first scene to a secondscene, the stereoscopic video module may be configured to detectmovement of one or more elements between frames of the first scene.Based on the movement of elements between frames in the first scene, thestereoscopic video module may be configured to generate the inferredframe for the first scene. Upon generating the inferred frame, thestereoscopic video module may be configured to generate a modified framefor the last frame of the first scene based on movement of elementsbetween the last frame of the first scene and the inferred frame.

For example, after detecting the change from scene 306 a to scene 306 b,the stereoscopic video module may be configured to detect movement ofone or more elements between frames 302 b and 302 c in response to thedetection of the scene change. Based on the detected movement betweenthe frames 302 b and 302 c, the stereoscopic video module may beconfigured to infer what movement may have occurred between the frame302 c and a subsequent frame in the scene 306 a had the scene 306 acontinued past the frame 302 c. In some embodiments, the inference ofmovement between elements may be made based on an assumption that themovement of elements between frames 302 b and 302 c would have continuedpast the frame 302 c had the scene 306 a not ended after the frame 302c. The stereoscopic video module may accordingly be configured togenerate the inferred frame 305 for the scene 306 a based on movement ofelements between frames 302 b and 302 c of the scene 306 a such that theinferred frame 305 may reflect movement that likely would have continuedin the scene 306 a had the scene 306 a continued past the frame 302 c.

Once the inferred frame 305 is generated, the stereoscopic video modulemay generate a modified frame 302 c′ based on the movement of one ormore elements between the frame 302 c and the inferred frame 305,similar to the generation of modified frames 302 a′ and 302 b′ based onmovement between frames 302 a and 302 b, and 302 b and 302 c,respectively. Therefore, the modified frame 302 c′ may be generatedbased on movement that may have occurred from the frame 302 c to asubsequent frame with substantially the same elements even though suchsubsequent frame may not exist.

Modifications, additions, or omissions may be made to FIG. 3 withoutdeparting from the scope of the present disclosure. For example, themonoscopic video 301 may include more or fewer frames 302 and/or scenes306 than those explicitly illustrated. Additionally, each scene 306 mayinclude any number of frames 302. Further, in some embodiments, one ormore intermediate frames may be included between the frames 302illustrated.

Returning to FIG. 1, as mentioned previously, the stereoscopic videomodule 104 may be configured to generate left-eye and right-eye viewingframes of the stereoscopic video 103 based on a camera effect and onmodified frames of the monoscopic video 101, which may be generatedbased on movement of elements between frames, as described above withrespect to FIGS. 2 and 3. Accordingly, the stereoscopic video module 104may also be configured to analyze a camera effect of the monoscopicvideo 101 in accordance with one or more embodiments of the presentdisclosure. In such embodiments, the stereoscopic video module 104 maydetermine whether the camera effect is a panning effect or a zoomingeffect and may generate the left-eye and right-eye viewing frames basedon whether the camera effect is a panning effect or a zooming effect.The generation of the left-eye viewing frame and the right-eye viewingframe based on a determination that the camera effect is a panningeffect is discussed in further detail below with respect to FIGS. 4 and5. The generation of the left-eye viewing frame and the right-eyeviewing frame based on a determination that the camera effect is azooming effect is discussed in further detail below with respect toFIGS. 6 and 7.

Additionally, if the stereoscopic video module 104 determines that thecamera effect is not a panning effect or a zooming effect, thestereoscopic video module 104 may generate the left-eye and right-eyeviewing frames according to this determination. In some of theseembodiments, the stereoscopic video module 104 may generate the left-eyeviewing frame and the right-eye viewing frame based on movement of theforeground and the background associated with the frames of themonoscopic video 101. The foreground and background detection isdescribed in greater detail with respect to FIGS. 8 and 9. Thegeneration of the left-eye viewing frame and the right-eye viewing framebased on a determination that the camera effect is not a panning effector a zooming effect is discussed in further detail below with respect toFIG. 10.

FIG. 4 illustrates an example block diagram 400 depicting the generationof a left-eye viewing frame 410 and a right-eye viewing frame 412 of astereoscopic video 403 based on a right-panning effect associated with aframe 402 a and a frame 402 b of a monoscopic video 401, according tosome embodiments of the present disclosure. In the illustrated example,the stereoscopic video 403 may be generated by a stereoscopic videomodule, such as the stereoscopic video module 104 described above withrespect to FIG. 1.

The frames 402 a and 402 b may include one or more elements 408 that mayeach be included in both the frame 402 a and the frame 402 b. Forexample, in the illustrated embodiment, the frames 402 a and 402 b mayeach include the elements 408 a and 408 b. The frames 402 a and 402 bmay also include other elements not expressly depicted in FIG. 4.

When a camera pans, the entire setting being filmed by the camera movesas the camera moves such that the elements within the frames associatedwith the panning effect may move in a substantially uniform magnitudeand direction. For example, the frames 402 a and 402 b may be associatedwith a right-panning effect where a camera generating the frames 402 aand 402 b may have been panned from the left to the right such that theelements 408 a and 408 b within the frames 402 a and 402 b may uniformlymove in substantially the same amount from the right to the left betweenthe frames 402 a and 402 b.

The right-panning effect may be generated based on an actual camerapanning from left to right, or may be generated based on a simulation ofa camera panning from left to right. In some embodiments, the panningeffect may be associated with a camera pivoting about an axis, or anysuitable simulation of such, to generate the panning effect. In otherembodiments, the panning effect may be associated with the entire cameramoving in a horizontal direction with respect to the setting beingfilmed (e.g., from the left to the right), or any suitable simulation ofsuch, to generate the panning effect.

The stereoscopic video module may be configured to determine whether aright-panning effect is present between the frames 402 a and 402 b basedon analyzing the movement of elements, such as the elements 408 a and408 b, between the frames 402 a and 402 b. For example, in someembodiments, the stereoscopic video module may analyze the movement ofdifferent elements located in different areas (e.g., the top-right,top-left, bottom-right, and bottom-left areas) of the frames 402 a and402 b. In some embodiments, the stereoscopic video module may analyzethe movement of the elements by analyzing the movement associated withthe pixels of the frames 402 a and 402 b that may correspond to theelements. In these or other embodiments, the stereoscopic video modulemay analyze movement associated with each pixel of the frames 402 a and402 b to determine the movement of elements between the frame 402 a andthe frame 402 b. If the movement associated with the elements (or insome embodiments the pixels) located in different areas of the frames402 a and 402 b all move substantially to the same degree from the rightto the left, the stereoscopic video module may determine that the cameraeffect is a right-panning effect.

The stereoscopic video module may generate a modified frame 402 a′associated with the frame 402 a based on the determined right-panningeffect and the movement associated therewith. For example, as mentionedabove, the right-panning effect may result in the elements 408 a and 408b moving from the right to the left to substantially the same degreefrom the frame 402 a to the frame 402 b. Accordingly, in someembodiments, the stereoscopic video module may generate the modifiedframe 402 a′ using the frame 402 b because of the difference inhorizontal positions of the elements 408 a and 408 b between the frames402 a and 402 b caused by the right-panning effect. In some embodiments,where there may be little to no vertical offset of the elements 408 aand 408 b between the frames 402 a and 402 b, the frame 402 b may beused as the modified frame 402 a′. In other embodiments where a verticaloffset may be present in the elements 408 a and 408 b between the frames402 a and 402 b, differences in the vertical positions of the elements408 a and 408 b between the frames 402 a and 402 b may be removed duringthe generation of the modified frame 402 a′ such that any verticaloffset of the elements 402 a and 402 b between the frame 402 a and themodified frame 402 a′ may be insubstantial.

The left-eye viewing frame 410 and the right-eye viewing frame 412 ofthe stereoscopic video 403, which may be associated with the viewingframe 402 a of the monoscopic video 401, may be generated based on theright-panning effect, the viewing frame 402 a, and the modified viewingframe 402 a′. For example, due to the right-panning effect, the frame402 a may be designated as the left-eye viewing frame 410 and themodified frame 402 a′ may be designated as the right-eye viewing frame412. Therefore, the left-eye viewing frame 410 and the right-eye viewingframe 412 of the stereoscopic video 403 may be generated based at leastpartially on the right-panning effect and the modified frame 402 a′,which may be associated with movement of the elements 408 a and 408 bbetween the frames 402 a and 402 b.

Modifications, additions, or omissions other than those explicitlydescribed may be made to the generation of the stereoscopic video 403.For example, left-eye and right-eye viewing frames associated with otherframes 402 of the monoscopic video 401 (e.g., left-eye and right-eyeviewing frames associated with the frame 402 b) may be generated in asimilar manner. Additionally, in some embodiments, left-eye andright-eye viewing frames may be generated for a frame 402 that may bethe last, or close to the last, frame of its respective scene such thatthe modified frame associated with the frame 402 may be generated basedon an inferred frame determined in a manner as described above withrespect to FIG. 3.

FIG. 5 illustrates an example block diagram 500 depicting the generationof a left-eye viewing frame 510 and a right-eye viewing frame 512 of astereoscopic video 503 based on a left-panning effect associated with aframe 502 a and a frame 502 b of a monoscopic video 501, according tosome embodiments of the present disclosure. In the illustrated example,the stereoscopic video 503 may be generated by a stereoscopic videomodule, such as the stereoscopic video module 104 described above withrespect to FIG. 1.

The frames 502 a and 502 b may include one or more elements 508 that mayeach be included in both the frame 502 a and the frame 502 b. Forexample, in the illustrated embodiment, the frames 502 a and 502 b mayeach include the elements 508 a and 508 b.

As mentioned above, the frames 502 a and 502 b may be associated with aleft-panning effect where a camera generating the frames 502 a and 502 bmay have been panned from the right to the left such that the elements508 within the frames 502 a and 502 b may uniformly move insubstantially the same amount from the left to the right between theframes 502 a and 502 b. For example, in the illustrated embodiment, theelements 508 a and 508 b may move from the left to the right between theframes 502 a and 502 b in substantially the same amount based on theleft-panning effect associated with the frames 502 a and 502 b.

Similar to the right-panning effect, the left-panning effect may begenerated based on an actual camera panning from right to left, or maybe generated based on a simulation of a camera panning from right toleft. Also, in some embodiments, the panning effect may be associatedwith a camera pivoting about an axis, or any suitable simulation ofsuch, to generate the panning effect. In other embodiments, the panningeffect may be associated with the entire camera moving in a horizontaldirection with respect to the setting being filmed (e.g., from the rightto the left), or any suitable simulation of such, to generate thepanning effect.

Similar to determining whether a right-panning effect is present, asdiscussed above with respect to FIG. 4, the stereoscopic video modulemay be configured to determine whether a left-panning effect is presentbetween the frames 502 a and 502 b based on analyzing the movementassociated with elements, such as the elements 508 a and 508 b, (or insome embodiments the pixels) between the frames 502 a and 502 b. If themovement associated with elements (or in some embodiments the pixels)located in different areas of the frames 502 a and 502 b all movesubstantially to the same degree from the left to the right, thestereoscopic video module may determine that the camera effect is aleft-panning effect.

The stereoscopic video module may generate a modified frame 502 a′associated with the frame 502 a based on the determined left-panningeffect and the movement associated therewith. For example, as mentionedabove, the left-panning effect may result in the elements 508 a and 508b moving from the left to the right to substantially the same degreefrom the frame 502 a to the frame 502 b. Accordingly, in someembodiments, the stereoscopic video module may generate the modifiedframe 502 a′ based on the frame 502 b because of the difference inhorizontal positions of the elements 508 a and 508 b between the frames502 a and 502 b caused by the left-panning effect. In some embodiments,where there may be little to no vertical offset of the elements 508 aand 508 b between the frames 502 a and 502 b, the frame 502 b may beused as the modified frame 502 a′. In other embodiments where a verticaloffset may be present in the elements 508 a and 508 b between the frames502 a and 502 b, differences in the vertical positions of the elements508 a and 508 b between the frames 502 a and 502 b may be removed duringthe generation of the modified frame 502 a′ such that any verticaloffset of the elements 508 a and 508 b between the frame 502 a and themodified frame 502 a′ may be insubstantial.

The left-eye viewing frame 510 and the right-eye viewing frame 512 ofthe stereoscopic video 503, which may be associated with the viewingframe 502 a of the monoscopic video 501, may be generated based on theleft-panning effect, the viewing frame 502 a, and the modified viewingframe 502 a′. For example, due to the left-panning effect, the modifiedframe 502 a′ may be designated as the left-eye viewing frame 510 and theframe 502 a may be designated as the right-eye viewing frame 512.Therefore, the left-eye viewing frame 510 and the right-eye viewingframe 512 of the stereoscopic video 503 may be generated based at leastpartially on the left-panning effect and the modified frame 502 a′,which may be associated with movement of the elements 508 a and 508 bbetween the frames 502 a and 502 b.

Modifications, additions, or omissions other than those explicitlydescribed may be made to the generation of the stereoscopic video 503.For example, left-eye and right-eye viewing frames associated with otherframes 502 of the monoscopic video 501 (e.g., left-eye and right-eyeviewing frames associated with the frame 502 b) may be generated in asimilar manner. Additionally, in some embodiments, left-eye andright-eye viewing frames may be generated for a frame 502 that may bethe last, or close to the last, frame of its respective scene such thatthe modified frame associated with the frame 502 may be generated basedon an inferred frame generated in a manner as described above withrespect to FIG. 3.

FIG. 6 illustrates an example block diagram 600 depicting the generationof a left-eye viewing frame 610 and a right-eye viewing frame 612 of astereoscopic video 603 based on a zooming-out camera effect associatedwith a frame 602 a and a frame 602 b of a monoscopic video 601,according to some embodiments of the present disclosure. In theillustrated example, the stereoscopic video 603 may be generated by astereoscopic video module, such as the stereoscopic video module 104described above with respect to FIG. 1.

The frames 602 a and 602 b may include one or more elements 608 that mayeach be included in both the frame 602 a and the frame 602 b. Forexample, in the illustrated embodiment, the frames 602 a and 602 b mayeach include the elements 608 a, 608 b, 608 c, and 608 d.

When a camera zooms out, the elements within the frames being generatedby the camera may move toward the center of the setting captured by theframes from one frame to another. For example, the frames 602 a and 602b may be associated with a zooming-out camera effect such that theelements 608 a, 608 b, 608 c, and 608 d within the frames 602 a and 602b may move toward the center of the setting captured by the frames 602 aand 602 b from the frame 602 a to the frame 602 b, as illustrated inFIG. 6. The zooming-out camera effect may be generated based on anactual camera zooming out, or may be generated based on a simulation ofzooming out.

Similar to determining whether a right-panning or left-panning effect ispresent, as discussed above with respect to FIGS. 4 and 5, thestereoscopic video module may be configured to determine whether azooming-out camera effect is present between the frames 602 a and 602 bbased on analyzing the movement between the frames 602 a and 602 b ofelements located in different areas (e.g., the top-left, top-right,bottom-left, and bottom-right areas) of the frames 602 a and 602 b, suchas the elements 608 a, 608 b, 608 c, and 608 d, which may be located inthe top-left, top-right, bottom-left, and bottom-right areas,respectively, of the frames 602 a and 602 b. In some embodiments, thestereoscopic video module may analyze the movement of the elements byanalyzing the movement associated with the pixels of the frames 602 aand 602 b that may correspond to the elements. In these or otherembodiments, the stereoscopic video module may analyze movementassociated with each pixel of the frames 602 a and 602 b to determinethe movement of elements between the frame 602 a and the frame 602 b. Ifthe movement associated with the elements (or in some embodiments thepixels) located in different areas of the frames 602 a and 602 b allmove substantially toward the center of the setting captured by theframes 602 a and 602 b, the stereoscopic video module may determine thatthe camera effect is a zooming-out camera effect.

The stereoscopic video module may generate a modified frame 602 a′ and amodified frame 602 a″ associated with the frame 602 a based on thedetermined zooming-out camera effect and the movement associatedtherewith. For example, the zooming-out camera effect may result in theelements included in left sides 614 a and 614 b of the frames 602 a and602 b, respectively, (e.g., the elements 608 a and 608 c) moving fromthe left to the right to substantially the same degree from the frame602 a to the frame 602 b. Additionally, the zooming-out camera effectmay result in the elements included in right sides 616 a and 616 b ofthe frames 602 a and 602 b, respectively, (e.g., the elements 608 b and608 d) moving from the right to the left to substantially the samedegree from the frame 602 a to the frame 602 b.

In some embodiments, the stereoscopic video module may generate a leftside 614 c of the modified frame 602 a′ based on the horizontal offsetof the elements between the left sides 614 a and 614 b of the frames 602a and 602 b, respectively. Additionally, the stereoscopic video modulemay ignore any vertical offset of the elements between the left sides614 a and 614 b during the generation of the left side 614 c. Forexample, the elements 608 a and 608 c may have substantially the samehorizontal position in the left side 614 c of the modified frame 602 a′as in the left side 614 b of the frame 602 b. However, the elements 608a and 608 c may have substantially the same vertical position in theleft side 614 c of the modified frame 602 a′ as in the left side 614 aof the frame 602 a.

Additionally, the stereoscopic video module may generate a right side616 c of the modified frame 602 a′ based on both the horizontal andvertical positions of the elements included in the right side 616 a ofthe frame 602 a such that the right side 616 c may be substantiallysimilar to the right side 616 a. For example, the elements 608 b and 608d may have substantially the same horizontal and vertical positions inthe right side 616 c of the modified frame 602 a′ as in the right side616 a of the frame 602 a.

The stereoscopic video module may also generate a right side 616 d ofthe modified frame 602 a″ based on the horizontal offset of the elementsbetween the right sides 616 a and 616 b of the frames 602 a and 602 b,respectively. Additionally, the stereoscopic video module may ignore anyvertical offset of the elements between the right sides 616 a and 616 bduring the generation of the right side 616 d. For example, the elements608 b and 608 d may have substantially the same horizontal position inthe right side 616 d of the modified frame 602 a″ as in the right side616 b of the frame 602 b. However, the elements 608 b and 608 d may havesubstantially the same vertical position in the right side 616 d of themodified frame 602 a″ as in the right side 616 a of the frame 602 a.

In contrast, the stereoscopic video module may generate a left side 614d of the modified frame 602 a″ based on both the horizontal and verticalpositions of the elements included in the left side 614 a of the frame602 a such that the left side 614 d may be substantially similar to theleft side 614 a. For example, the elements 608 a and 608 c may havesubstantially the same horizontal and vertical positions in the leftside 614 d of the modified frame 602 a″ as in the left side 614 a of theframe 602 a.

As depicted in FIG. 6, the configuration of the modified frames 602 a′and 602 a″ for a zooming-out effect described above may result in theelements 608 a, 608 b, 608 c, and 608 d being horizontally offset to theright in the modified frame 602 a′ with respect to the modified frame602 a″. Additionally, the elements 608 a, 608 b, 608 c, and 608 d mayhave little to no vertical offset in the modified frame 602 a′ withrespect to the modified frame 602 a″.

The left-eye viewing frame 610 and the right-eye viewing frame 612 ofthe stereoscopic video 603, which may be associated with the viewingframe 602 a of the monoscopic video 601, may be generated based on thezooming-out camera effect and the modified viewing frames 602 a′ and 602a″. For example, due to the zooming-out camera effect, the modifiedframe 602 a′ may be designated as the left-eye viewing frame 610 and themodified frame 602 a″ may be designated as the right-eye viewing frame612. Therefore, the left-eye viewing frame 610 and the right-eye viewingframe 612 of the stereoscopic video 603 may be generated based at leastpartially on the zooming-out camera effect and the modified frames 602a′ and 602 a″, which may be associated with movement of the elements 608a, 608 b, 608 c, and 608 d between the frames 602 a and 602 b.

Modifications, additions, or omissions other than those explicitlydescribed may be made to the generation of the stereoscopic video 603.For example, left-eye and right-eye viewing frames associated with otherframes 602 of the monoscopic video 601 (e.g., left-eye and right-eyeviewing frames associated with the frame 602 b) may also be generated ina similar manner. Additionally, in some embodiments, left-eye andright-eye viewing frames may be generated for a frame 602 that may bethe last, or close to the last, frame of its respective scene such thatthe modified frames associated with the frame 602 may be generated basedon the frame 602 and an associated inferred frame generated in a manneras described above with respect to FIG. 3.

FIG. 7 illustrates an example block diagram 700 depicting the generationof a left-eye viewing frame 710 and a right-eye viewing frame 712 of azooming-in camera effect associated with a frame 702 a and a frame 702 bof a monoscopic video 701, according to some embodiments of the presentdisclosure. The frames 702 a and 702 b may include one or more elements708 that may each be included in both the frame 702 a and the frame 702b. For example, in the illustrated embodiment, the frames 702 a and 702b may each include the elements 708 a, 708 b, 708 c, and 708 d.

When a camera zooms in, the elements within the frames being generatedby the camera may move away from the center of the setting captured bythe frames from one frame to another. For example, the frames 702 a and702 b may be associated with a zooming-in camera effect such that theelements 708 a, 708 b, 708 c, and 708 d within the frames 702 a and 702b may move away from the center of the setting captured by the frames702 a and 702 b from the frame 702 a to the frame 702 b, as illustratedin FIG. 7. The zooming-in camera effect may be generated based on anactual camera zooming in, or may be generated based on a simulation of azooming in.

Similar to determining whether a right-panning, left-panning, orzooming-out camera effect is present, as discussed above with respect toFIGS. 4-6, the stereoscopic video module may be configured to determinewhether a zooming-in camera effect is present between the frames 702 aand 702 b based on analyzing the movement between the frames 702 a and702 b of elements located in different areas (e.g., the top-right,top-left, bottom-right, and bottom-left areas) of the frames 702 a and702 b, such as the elements 708 a, 708 b, 708 c, and 708 d. In someembodiments, the stereoscopic video module may analyze the movement ofthe elements by analyzing the movement associated with the pixels of theframes 702 a and 702 b that may correspond to the elements. In these orother embodiments, the stereoscopic video module may analyze movementassociated with each pixel of the frames 702 a and 702 b to determinethe movement of elements between the frame 702 a and the frame 702 b. Ifthe movement associated with the elements (or in some embodiments thepixels) located in different areas of the frames 702 a and 702 b allmove substantially away from the center of the setting captured by theframes 702 a and 702 b, the stereoscopic video module may determine thatthe camera effect is a zooming-in camera effect.

The stereoscopic video module may generate a modified frame 702 a′ and amodified frame 702 a″ associated with the frame 702 a based on thedetermined zooming-in camera effect and the movement associatedtherewith. For example, the zooming-in camera effect may result in theelements included in left sides 714 a and 714 b of the frames 702 a and702 b, respectively, (e.g., the elements 708 a and 708 c) moving fromthe right to the left to substantially the same degree from the frame702 a to the frame 702 b. Additionally, the zooming-in camera effect mayresult in the elements included in the right sides 716 a and 716 b ofthe frames 702 a and 702 b, respectively, (e.g., the elements 708 b and708 d) moving from the left to the right to substantially the samedegree from the frame 702 a to the frame 702 b.

In some embodiments, the stereoscopic video module may generate a leftside 714 c of the modified frame 702 a′ based on the horizontal offsetof the elements between the left sides 714 a and 714 b of the frames 702a and 702 b, respectively. Additionally, the stereoscopic video modulemay ignore any vertical offset of the elements between the left sides714 a and 714 b during the generation of the left side 714 c. Forexample, the elements 708 a and 708 c may have substantially the samehorizontal position in the left side 714 c of the modified frame 702 a′as in the left side 714 b of the frame 702 b. However, the elements 708a and 708 c may have substantially the same vertical position in theleft side 714 c of the modified frame 702 a′ as in the left side 714 aof the frame 702 a.

Additionally, the stereoscopic video module may generate a right side716 c of the modified frame 702 a′ based on both the horizontal andvertical positions of the elements included in the right side 716 a ofthe frame 702 a such that the right side 716 c may be substantiallysimilar to the right side 716 a. For example, the elements 708 b and 708d may have substantially the same horizontal and vertical positions inthe right side 716 c of the modified frame 702 a′ as in the right side716 a of the frame 702 a.

The stereoscopic video module may also generate a right side 716 d ofthe modified frame 702 a″ based on the horizontal offset of the elementsbetween the right sides 716 a and 716 b of the frames 702 a and 702 b,respectively. Additionally, the stereoscopic video module may ignore anyvertical offset of the elements between the right sides 716 a and 716 bduring the generation of the right side 716 d. For example, the elements708 b and 708 d may have substantially the same horizontal position inthe right side 716 d of the modified frame 702 a″ as in the right side716 b of the frame 702 b. However, the elements 708 b and 708 d may havesubstantially the same vertical position in the right side 716 d of themodified frame 702 a″ as in the right side 716 a of the frame 702 a.

Further, the stereoscopic video module may generate a left side 714 d ofthe modified frame 702 a″ based on both the horizontal and verticalpositions of the elements included in the left side 714 a of the frame702 a such that the left side 714 d may be substantially similar to theleft side 714 a. For example, the elements 708 a and 708 c may havesubstantially the same horizontal and vertical positions in the leftside 714 d of the modified frame 702 a″ as in the left side 714 a of theframe 702 a.

As depicted in FIG. 7, the configuration of the modified frames 702 a′and 702 a″ for a zooming-in effect described above may result in theelements 708 a, 708 b, 708 c, and 708 d being horizontally offset to theleft in the modified frame 702 a′ with respect to the modified frame 702a″. Additionally, the elements 708 a, 708 b, 708 c, and 708 d may havelittle to no vertical offset in the modified frame 702 a′ with respectto the modified frame 702 a″.

The left-eye viewing frame 710 and the right-eye viewing frame 712 ofthe stereoscopic video 703, which may be associated with the viewingframe 702 a of the monoscopic video 701, may be generated based on thezooming-in camera effect and the modified viewing frames 702 a′ and 702a″. For example, due to the zooming-in camera effect, the modified frame702 a″ may be designated as the left-eye viewing frame 710 and themodified frame 702 a′ may be designated as the right-eye viewing frame712. Therefore, the left-eye viewing frame 710 and the right-eye viewingframe 712 of the stereoscopic video 703 may be generated based at leastpartially on the zooming-in camera effect and the modified frames 702 a′and 702 a″, which may be associated with movement of the elements 708 a,708 b, 708 c, and 708 d between the frames 702 a and 702 b.

Modifications, additions, or omissions other than those explicitlydescribed may be made to the generation of the stereoscopic video 703.For example, left-eye and right-eye viewing frames associated with otherframes 702 of the monoscopic video 701 (e.g., left-eye and right-eyeviewing frames associated with the frame 702 b) may also be generated ina similar manner. Additionally, in some embodiments, left-eye andright-eye viewing frames may be generated for a frame 702 that may bethe last, or close to the last, frame of its respective scene such thatthe modified frames associated with the frame 702 may be generated basedon the frame 702 and a corresponding inferred frame generated in amanner as described above with respect to FIG. 3.

Returning to FIG. 1, the stereoscopic video module 104 may accordinglybe configured to generate left-eye and right-eye viewing frames for thestereoscopic video 103 based on panning or zooming effects as describedabove with respect to FIGS. 4-7. However, in some instances a cameraeffect may be something different from a panning or zooming effect. Forexample, the camera effect may be a rotating camera effect or astationary camera effect. In such instances, the stereoscopic videomodule 104 may determine that the camera effect is not a panning orzooming effect and may generate the left-eye and right-eye viewingframes according to this determination. In some of these embodiments,the stereoscopic video module 104 may generate the left-eye viewingframe and the right-eye viewing frame based on the determination thatthe camera effect is not a panning or zooming effect and based onmovement of the foreground and/or the background associated with theframes of the monoscopic video 101.

Accordingly, in some embodiments, the stereoscopic video module 104 maybe configured to determine at least one of the foreground and thebackground associated with the monoscopic video 101 such that thestereoscopic video module may analyze movement associated with theforeground and/or the background. In some of these embodiments, thestereoscopic video module 104 may be configured to determine, based onframes of the monoscopic video 101, a fastest-moving element, aslow-moving element, and/or a dominant element associated with theframes of the monoscopic video 101 to determine the foreground and/orbackground.

FIG. 8 illustrates example frames 802 a and 802 b of a monoscopic video801 where the frames 802 a and 802 b include a fastest-moving element820, a slow-moving element 822 and a dominant element 824, in accordancewith some embodiments of the present disclosure. The monoscopic video801 may be substantially similar to the monoscopic video 101 of FIG. 1.In the illustrated embodiment, the frames 802 a and 802 b may beassociated with the same scene of the monoscopic video 801 and the frame802 b may be a subsequent frame of the frame 802 a. A stereoscopic videomodule, such as the stereoscopic video module 104 of FIG. 1, may beconfigured to identify the fastest-moving element 820, the slow-movingelement 822, and/or the dominant element 824.

The stereoscopic video module may analyze the frames 802 a and 802 b todetermine the fastest-moving element 820, the slow-moving element 822,and/or the dominant element 824. For example, the stereoscopic videomodule may analyze the displacement of elements in the frame 802 b withrespect to the frame 802 a to identify the fastest-moving element 820and the slow-moving element 822. A fast-moving element may move afurther distance than a slow-moving element from the frame 802 a to theframe 802 b. Therefore, the stereoscopic video module may analyze thedisplacement of elements from the frame 802 a to the frame 802 b, andthe element with the greatest amount of displacement may be determinedto be the fastest-moving element.

In the illustrated embodiment, the fastest-moving element 820 may havethe largest displacement from the frame 802 a to the frame 802 b suchthat the stereoscopic video module may identify the fastest-movingelement 820 as the fastest-moving element from the frame 802 a to theframe 802 b. Additionally, as illustrated in FIG. 8, the slow-movingelement 822 may also move between the frame 802 a to the frame 802 b,but to a smaller degree than the fastest-moving element 820.Accordingly, the stereoscopic video module may identify the slow-movingelement 822 as a slower-moving element than the fastest-moving element820.

Additionally, the stereoscopic video module may be configured todetermine that the dominant element 824 is a dominant element within theframes 802 a and 802 b. In some embodiments, the stereoscopic videomodule may identify elements within the frames 802 a and 802 b based onan analysis of the pixels associated with the frames 802 a and 802 bsuch that the number of pixels associated with a particular element maybe determined. Accordingly, in some embodiments, the stereoscopic videomodule may be configured to identify the dominant element 824 based onthe dominant element 824 being associated with a substantially highernumber of pixels than other elements included in the frames 802 a and802 b. Therefore, by analyzing the frames 802 a and 802 b, thestereoscopic video module may be able to identify the fastest-movingelement 820, the slow-moving element 822, and/or the dominant element824. As detailed below, identification of these elements may help in adetermination of the foreground and/or background associated with theframes 802 a and 802 b.

The illustration of FIG. 8 is merely to introduce the concepts behind afastest-moving element, a slow-moving element and a dominant element.Accordingly, modifications, additions, or omissions may be made to FIG.8 without departing from the scope of the present disclosure. In someembodiments, the amount of displacement between the frames 802 a and 802b of the fastest-moving element 820 and the slow-moving element 822 mayvary based on differences in speed of the fastest-moving element 820 andthe slow-moving element 822. For example, in some instances, thefastest-moving element 820 and the slow-moving element 822 may move atsubstantially the same speed such that the displacement between theframes 802 a and 802 b of the fastest-moving element 820 and theslow-moving element 822 may be substantially the same. Additionally, insome embodiments, the dominant element 824 may move between the frames802 a and 802 b, while in other embodiments, the dominant element 824may not move. Further, in some instances, the frames 802 a and 802 b maynot include a dominant element. Also, the direction of movement of thefastest-moving element 820, the slow-moving element 822, and/or thedominant element 824 may vary.

As mentioned above, the foreground and/or background of a scene may bedetermined based on a fastest-moving element, a slow-moving element,and/or a dominant element associated with the scene. FIG. 9 is aflowchart of an example method 900 of determining the foreground and/orbackground of a scene based on at least one of a fastest-moving element,a slow-moving element and a dominant element associated with the scene,according to some embodiments of the present disclosure. The method 900may be implemented, in some embodiments, by a stereoscopic video module,such as the stereoscopic video module 104 of FIG. 1. For instance, thestereoscopic video module 104 may be configured to execute computerinstructions to perform operations for determining the foreground and/orthe background as represented by one or more of the blocks of the method900. Although illustrated as discrete blocks, various blocks may bedivided into additional blocks, combined into fewer blocks, oreliminated, depending on the desired implementation.

The method 900 may begin at block 902 where movement of elements and/orpixels between a first frame and a second frame may be determined. Atblock 904, it may be determined whether all the elements and/or pixelsare moving in substantially the same direction. If all the elementsand/or pixels are moving in substantially the same direction, the method900 may proceed to block 906. If all the elements and/or pixels are notmoving in substantially the same direction, the method 900 may proceedto block 914.

At block 906, a fastest-moving element and a slow-moving elementassociated with the first frame and the second frame may be determined.In some embodiments, the fastest-moving element and the slow-movingelement may be determined based on the displacement of elements in thesecond frame with respect to the first frame such as described abovewith respect to the fastest-moving element 820 and the slow-movingelement 822 between frames 802 a and 802 b of FIG. 8.

At block 908, it may be determined whether there is a significant speeddifference between the fastest-moving element and the slow movingelement. If there is a significant speed difference, the method 900 mayproceed to block 910. If there is not a significant speed difference,the method 900 may proceed to block 912. In some embodiments, the speeddifference may be determined by measuring the difference in the offsetsof the fastest-moving element and the slow-moving element from the firstframe to the second frame. Additionally, in some embodiments, the speeddifference (e.g., difference in offset) may be compared to a thresholdand if the speed difference is greater than the threshold, the method900 may proceed to block 910 and if the speed difference is less thanthe threshold, the method 900 may proceed to block 912. In someinstances, the threshold may vary according to the type of movie. Forexample, the threshold may be higher for an action movie than for adrama.

At block 910, with the speed difference between the fastest-movingelement and the slow-moving element being substantially large enough(e.g., greater than the threshold), the foreground may be correlatedwith the fastest-moving element such that the fastest-moving element maybe considered to be in the foreground. At block 912, with the speeddifference between the fastest-moving element and the slow-movingelement not being substantially large enough (e.g., less than thethreshold), the background may be correlated with the entire sceneassociated with the first frame and the second frame. Therefore, atblock 912, the entire scene associated with the first frame and thesecond frame may be considered to be in the background.

Returning to block 904, as mentioned above, if the movement of all theelements and/or pixels are not the same, the method 900 may proceed toblock 914. At block 914, it may be determined whether a dominant elementis present in the scene associated with the first and second frames. Insome embodiments, the determination of whether or not a dominant elementis present may be determined based on the number of pixels associatedwith each element, such as described above with respect to the dominantelement 824 of FIG. 8. If a dominant element is present, the method 900may proceed to block 916. If a dominant element is not present, themethod 900 may proceed to block 922.

At block 916, it may be determined whether or not the dominant elementdetermined in block 914 is substantially at the center of the sceneassociated with the first and second frames. If the dominant element issubstantially at the center, the method 900 may proceed to block 918. Ifthe dominant element is not substantially at the center, the method 900may proceed to block 920.

At block 918, with the dominant element substantially at the center ofthe scene, the foreground may be correlated with the dominant elementsuch that the dominant element may be considered the foreground. Atblock 920, with the dominant element not substantially at the center ofthe scene, the background may be correlated with the dominant elementsuch that the dominant element may be considered the background.

Returning to block 914, if it is determined that no dominant element ispresent, the method 900 may proceed to block 922, as mentioned above. Atblock 922, a fastest-moving element and a slow-moving element associatedwith the first frame and the second frame may be determined, similar toas done in block 906. At block 924, it may be determined whether thereis a significant speed difference between the fastest-moving element andthe slow-moving element, similar to as done in block 908. If there is asignificant speed difference, the method 900 may proceed to block 926.If there is not a significant speed difference, the method 900 mayproceed to block 928.

At block 926, with the speed difference between the fastest-movingelement and the slow-moving element being substantially large enough,the foreground may be correlated with the fastest-moving element suchthat the fastest-moving element may be considered to be in theforeground. At block 928, with the speed difference between thefastest-moving element and the slow-moving element not beingsubstantially large enough, the background or the foreground may becorrelated with the entire scene associated with the first frame and thesecond. Therefore, at block 928, the entire scene associated with thefirst frame and the second frame may be considered to be in thebackground or the foreground.

Therefore, the method 900 may be used to determine the background and/orthe foreground of a scene. One skilled in the art will appreciate that,for this and other processes and methods disclosed herein, the functionsperformed in the processes and methods may be implemented in differingorder. Furthermore, the outlined steps and operations are only providedas examples, and some of the steps and operations may be optional,combined into fewer steps and operations, or expanded into additionalsteps and operations without detracting from the essence of thedisclosed embodiments.

Returning to FIG. 1, as mentioned above, in some embodiments where thestereoscopic video module 104 may determine that a camera effect is nota panning or zooming effect, the stereoscopic video module 104 maygenerate the left-eye viewing frame and the right-eye viewing framebased on movement of the foreground and/or the background associatedwith the frames of the monoscopic video 101.

FIG. 10 illustrates an example block diagram 1000 for generating aleft-eye viewing frame 1010 and a right-eye viewing frame 1012 of astereoscopic video 1003 from a monoscopic video 1001 based on movementof the foreground and/or background associated with the monoscopic video1001, according to some embodiments described herein. The left-eyeviewing frame 1010 and the right-eye viewing frame 1012 may be generatedby a stereoscopic video module, such as the stereoscopic video module104 of FIG. 1. The left-eye viewing frame 1010 and the right-eye viewingframe 1012 of the stereoscopic video 1003 may correspond to the frame1002 a of the monoscopic video 1001 and may be generated based on theframe 1002 a and its associated modified frame 1002 a′. In theillustrated embodiment, the modified frame 1002 a′ may be generatedbased on movement between frames 1002 a and 1002 b in a manner such asdescribed above with respect to FIG. 2; however, in other embodiments,the modified frame 1002 a′ may be generated using an inferred frame in amanner as described above with respect to FIG. 3.

In the illustrated embodiment, the stereoscopic video module may alsogenerate the left-eye viewing frame 1010 and the right-eye viewing frame1012 based on a determination that a camera effect associated with theframes 1002 a and 1002 b is not a panning or zooming effect and based onrelative movement of the background and foreground associated with theframes 1002 a and 1002 b (and consequently based on the modified frame1002 a′ also). In some embodiments, the stereoscopic video module maydetermine the background and foreground using the method 900 describedabove with respect to FIG. 9. In other embodiments, the background andforeground may be determined in any other suitable manner.

For example, in some instances the foreground may be moving faster thanthe background between the frames 1002 a and 1002 b, and thestereoscopic video module may determine as such. In such instances, ifthe foreground is moving to the right, and regardless of which directionthe background may be moving, the stereoscopic video module maydesignate the frame 1002 a as the left-eye viewing frame 1010 and maydesignate the modified frame 1002 a′ as the right-eye viewing frame1012. Additionally, in such instances, if the foreground is moving tothe left, and regardless of which direction the background may bemoving, the stereoscopic video module may designate the modified frame1002 a′ as the left-eye viewing frame 1010 and may designate the frame1002 a as the right-eye viewing frame 1012.

In other instances, the background may be moving faster than theforeground between the frames 1002 a and 1002 b, and the stereoscopicvideo module may determine as such. In such instances, if the backgroundis moving to the left, and regardless of which direction the foregroundmay be moving, the stereoscopic video module may designate the frame1002 a as the left-eye viewing frame 1010 and may designate the modifiedframe 1002 a′ as the right-eye viewing frame 1012. Additionally, in suchinstances, if the background is moving to the right, and regardless ofwhich direction the foreground may be moving, the stereoscopic videomodule may designate the modified frame 1002 a′ as the left-eye viewingframe 1010 and may designate the frame 1002 a as the right-eye viewingframe 1012.

Accordingly, the stereoscopic video module may be configured to generatethe left-eye viewing frame 1010 and the right-eye viewing frame 1012based on relative movement of the background and foreground associatedwith the frames 1002 a and 1002 b (and consequently based on themodified frame 1002 a′ also) in accordance with a determination that acamera effect associated with the frames 1002 a and 1002 b is not apanning or zooming effect.

Modifications, additions, or omissions may be made to FIG. 10 withoutdeparting from the scope of the present disclosure. For example, asmentioned above, in the illustrated embodiment, the frame 1002 b may besubsequent to the frame 1002 a and the modified frame 1002 a′ may begenerated based on movement between the frames 1002 a and 1002 b.However, in some instances, such as where a modified frame is beinggenerated for the last, or close to last, frame of a particular scene,the modified frame of such an instance may be generated based on aninferred frame as described above with respect to FIG. 3. Additionally,the foreground and background may be detected according to the method900 of FIG. 9 in some embodiments, and in other embodiments, theforeground and background may be detected in some other acceptablemanner.

The above description of FIGS. 1-10 illustrates that a stereoscopicvideo module (e.g., the stereoscopic video module 104 of FIG. 1) may beconfigured to generate left-eye and right-eye viewing frames for astereoscopic video based on movement between frames of the monoscopicvideo and a determined camera effect associated with a monoscopic video,according to some embodiments described herein. FIG. 11 is a flowchartof an example method 1100 of converting a monoscopic video into astereoscopic video based on a camera effect, according to someembodiments of the present disclosure. The method 1100 may beimplemented, in some embodiments, by a stereoscopic video module, suchas the stereoscopic video module 104 of FIG. 1. For instance, thestereoscopic video module 104 may be configured to execute computerinstructions to perform operations for converting a monoscopic videointo a stereoscopic video as represented by one or more of the blocks ofthe method 1100. Although illustrated as discrete blocks, various blocksmay be divided into additional blocks, combined into fewer blocks, oreliminated, depending on the desired implementation.

Method 1100 may begin, and at block 1102, movement between a first frameof a monoscopic video and a second frame of the monoscopic video may bedetermined. At block 1104 a modified first frame may be generated basedon the movement. In some embodiments, the modified first frame may begenerated based on the description given with respect to FIG. 2. Inother embodiments, the modified first frame may be generated based on aninferred frame as described with respect to FIG. 3.

At block 1106, a camera effect may be analyzed and determined based onthe movement. For example, the camera effect may be determined to be apanning effect, a zooming effect, or neither. At block 1108, a left-eyeviewing frame of a stereoscopic video may be generated based on thecamera effect analysis and at least one of the first frame and themodified first frame. At block 1110, a right-eye viewing frame of thestereoscopic video may be generated based on the camera effect analysisand at least one of the first frame and the modified first frame. In thecase of the zooming effect, in some embodiments a second modified firstframe may also be generated based on the first frame and the secondframe, and the left-eye and right-eye viewing frames may be generatedbased on at least one of the first modified first frame and the secondmodified first frame. In some embodiments, the left-eye and right-eyeviewing frames may be generated in accordance with the descriptionsgiven in FIGS. 4-10.

Therefore, the method 1100 may be used to convert a monoscopic videointo a stereoscopic video. One skilled in the art will appreciate that,for this and other processes and methods disclosed herein, the functionsperformed in the processes and methods may be implemented in differingorder. Furthermore, the outlined steps and operations are only providedas examples, and some of the steps and operations may be optional,combined into fewer steps and operations, or expanded into additionalsteps and operations without detracting from the essence of thedisclosed embodiments.

For example, in some embodiments, the method 1100 may include stepsassociated with determining the background and/or foreground which may,in turn, be used for generating the stereoscopic video, such asdescribed above with respect to FIGS. 9 and 10. In other embodiments,the foreground and background may be determined in another manner, ormay be designated by an input.

Returning to FIG. 1, as mentioned above, the stereoscopic video module104 may also be configured to adjust the amount of depth associated withthe stereoscopic video 103 by adjusting the offset between elementsincluded in the left-eye and right-eye viewing frames. As also mentionedabove, in some embodiments, the stereoscopic video module 104 may alsobe configured to adjust a focus point of the stereoscopic video 103 suchthat the stereoscopic video module 104 may modify the perception ofwhich elements may be within the foreground or background of a settingas perceived by the viewer. The adjustment of depth and the adjustmentof the focus point are described below with respect to FIGS. 12A through14.

FIG. 12A illustrates an example setting 1200 that may be perceived by aleft eye 1202 and a right eye 1204, according to some embodiments. Thesetting 1200 may include a near element 1206, a midrange element 1208,and a far element 1210. In the illustrated example, the left eye 1202and the right eye 1204 may be focused on the midrange element 1208 suchthat the midrange element 1208 may be at the focus point of the left eye1202 and the right eye 1204. Therefore, the near element 1206 may bewithin the foreground as perceived by the left eye 1202 and the righteye 1204. Additionally, due to the left eye 1202 and the right eye 1204being focused on the midrange element 1208, the far element 1210 may bewithin the background as perceived by the left eye 1202 and the righteye 1204.

FIG. 12B depicts an example grid 1201 that illustrates example offsetsthat may be found between the elements 1206, 1208, and 1210 in aleft-eye viewing frame and a right-eye viewing frame of a stereoscopicvideo associated with the setting 1200, according to some embodimentsdisclosed herein. As mentioned above, the offsets of the elements 1206,1208, and 1210 may mimic the different perspectives of the left eye 1202and the right eye 1204 with respect to the setting 1200.

In the illustrated embodiment, a left-near element 1206 a may representthe near element 1206 of FIG. 12A from the perspective of the left eye1202 of FIG. 12A and a right-near element 1206 b may represent the nearelement 1206 of FIG. 12A from the perspective of the right eye 1204 ofFIG. 12A. Therefore, the difference in position of the left-near element1206 a with respect to the right-near element 1206 b in the grid 1201may represent the offset of the near element 1206 in the left-eyeviewing frame with respect to the right-eye viewing frame of theassociated stereoscopic video.

In the illustrated embodiment, the left-near element 1206 a may be onthe right because, as illustrated in FIG. 12A, the near element 1206 maybe to the right of a line of sight 1212 associated with the left eye1202. Additionally, the right-near element 1206 b may be on the leftbecause the near element 1206 may be to the left of a line of sight 1214associated with the right eye 1204. This phenomenon is often referred toas “negative parallax” and occurs with objects that are in front of thefocus point of two eyes, which may be set to be at the midrange element1208 in the illustrated embodiment.

The midrange element 1208 a/b of the grid 1201 may represent themidrange element 1208 of FIG. 12A from the perspective of both the lefteye 1202 and the right eye 1204 of FIG. 12A. In the illustratedembodiment of FIG. 12A, the midrange element 1208 may be at the focuspoint of the left eye 1202 and the right eye 1204 such that there may belittle to no offset between the perspectives of the left eye 1202 andthe right eye 1204. Therefore, the midrange element 1208 may be insubstantially the same place in the right-eye viewing frame and theleft-eye viewing frame of the associated stereoscopic video. Themidrange element 1208 a/b of FIG. 12B accordingly illustrates theoverlap of a left-midrange element 1208 a as perceived by the left eye1202 and a right-midrange element 1208 b as perceived by the right eye1204.

Additionally, a left-far element 1210 a and a right-far element 1210 bmay represent the far element 1210 of FIG. 12A from the perspective ofthe left eye 1202 and right eye 1204, respectively, of FIG. 12A.Therefore, the difference in position of the left-far element 1210 awith respect to the right-far element 1210 b in the grid 1201 mayrepresent the offset of the far element 1210 in the left-eye viewingframe with respect to the right-eye viewing frame of the associatedstereoscopic video.

In the illustrated embodiment, the left-far element 1210 a may be on theleft because, as illustrated in FIG. 12A, the far element 1210 may be onthe left of the line of sight 1212 associated with the left eye 1202.Further, the right-far element 1210 b may be on the right because thefar element 1210 may be to the right of the line of sight 1214associated with the right eye 1204. This phenomenon is often referred toas “positive parallax” and occurs with objects that are behind the focuspoint of two eyes, which may be at the midrange element 1208 in theillustrated embodiment.

The amount of depth of a stereoscopic video may be adjusted by adjustingthe offset between corresponding elements of a left-eye viewing frameand its associated right-eye viewing frame. For example, the amount ofdepth associated with the stereoscopic video associated with FIG. 12Bmay be adjusted by adjusting the offset between the left-near element1206 a and the right-near element 1206 b, by adjusting the offsetbetween the left-midrange element 1208 a and the right-midrange element1208 b, and/or by adjusting the offset between the left-far element 1210a and the right-far element 1210 b. In some embodiments of the presentdisclosure, the depth may be adjusted by applying a uniform multiplyingfactor to the offsets between elements.

FIG. 12C depicts an example grid 1203 that illustrates the offsets ofthe elements of FIG. 12B with respect to their respective left-eye andright-eye viewing frames after applying a uniform multiplying factor tothe offsets of FIG. 12B, according to some embodiments disclosed herein.The uniform multiplying factor may be applied to the offsets associatedwith substantially all the elements in the left-eye and the right-eyeviewing frames such that the offsets between the elements are adjustedby substantially the same scale. In the illustrated embodiment, theuniform multiplying factor may have a value of two and may be applied tothe offsets between the elements 1206, 1208, and 1210 of FIG. 12B suchthat the offsets between the elements 1206, 1208, and 1210 in FIG. 12Cmay each be doubled with respect to the corresponding offsets in FIG.12B.

For example, in FIG. 12B a near element offset between the center of theleft-near element 1206 a and the center of the right-near element 1206 bmay be approximately “2” grid units. Therefore, applying a multiplyingfactor of “2” to the near element offset may result in the near elementoffset between the center of the left-near element 1206 a and the centerof the right-near element 1206 b in FIG. 12C being approximately “4”grid units, as illustrated in FIG. 12C.

Additionally, a midrange element offset between the left-midrangeelement 1208 a and the right-midrange element 1208 b may beapproximately “0” grid units. Therefore, applying a multiplying factorof “2” to the midrange element offset may result in the midrange elementoffset between the left-midrange element 1208 a and the right-midrangeelement 1208 b in FIG. 12C still being approximately “0” grid unitsbecause a number multiplied by “0” is still “0.”

Further, in FIG. 12B a far element offset between the center of theleft-far element 1210 a and the center of the right-far element 1210 bmay be approximately “3” grid units. Therefore, applying a multiplyingfactor of “2” to the far element offset may result in the far elementoffset between the center of the left-far element 1210 a and the centerof the right-far element 1210 b in FIG. 12C being approximately “6” gridunits, as illustrated in FIG. 12C.

In the illustrated embodiment, the right-near element 1206 b associatedwith the right-eye viewing frame may be shifted to the left byapproximately “2” grid units and the left-near element 1206 a associatedwith the left-eye viewing frame may not be shifted in FIG. 12C withrespect to FIG. 12B. Additionally, in the illustrated embodiment, theright-far element 1210 b associated with the right-eye viewing frame maybe shifted to the right by “3” grid units and the left-far element 1210a associated with the left-eye viewing frame may not be shifted in FIG.12C with respect to FIG. 12B. Therefore, the near element offset mayincrease from “2” grid units to “4” grid units and the far elementoffset may increase from “3” grid units to “6” grid units in FIG. 12Cwith respect to FIG. 12B by adjusting the right-eye viewing framewithout having to adjust the left-eye viewing frame also.

In alternative embodiments, in FIG. 12C with respect to FIG. 12B, thenear element offset and the far element offset may be adjusted byshifting the left-near element 1206 a and the left-far element 1210 awithin the left-eye viewing frame instead of shifting the right-nearelement 1206 b and the right-far element 1210 b in the right-eye viewingframe. In other embodiments, in FIG. 12C with respect to FIG. 12B, thenear element offset may be adjusted by shifting both the left-nearelement 1206 a and the right-near element 1206 b. Further, in some ofthese or other embodiments, in FIG. 12C with respect to FIG. 12B, thefar element offset may be adjusted by shifting both the left-far element1210 a and the right-far element 1210 b.

Although a specific uniform multiplying factor of “2” is used in theabove example, any suitable multiplying factor may be used. For example,any suitable multiplying factor greater than “1” may be used to increasethe amount of depth perceived by a viewer. Additionally, any suitablemultiplying factor less than “1” may be used to decrease the amount ofdepth perceived by a viewer. Further, although the uniform multiplyingfactor is described above as being applied to offsets associated withcorresponding elements, in some embodiments, the elements may eachinclude one or more pixels, and the uniform multiplying factor may beapplied to offsets associated with corresponding pixels. In someembodiments, the uniform multiplying factor may be applied to everyoffset associated with every element and/or pixel.

Accordingly, in accordance with some embodiments of the presentdisclosure, a stereoscopic video module (e.g., the stereoscopic videomodule 104) may be configured to adjust depth associated with astereoscopic video by applying a uniform multiplying factor to theoffsets between corresponding elements and/or pixels associated with theleft-eye viewing frames and the corresponding right-eye viewing framesof the stereoscopic video. In contrast, traditional depth adjustmentprocedures may not apply uniform scaling of the offsets to adjust thedepth.

The focus point of a stereoscopic video may also be adjusted byadjusting the offsets between corresponding elements of a left-eyeviewing frame and its associated right-eye viewing frame. For example,the focus point of the stereoscopic video associated with FIG. 12B maybe adjusted by adjusting the offset between the left-near element 1206 aand the right-near element 1206 b, by adjusting the offset between theleft-far element 1210 a and the right-far element 1210 b, and byadjusting the offset between the left-midrange element 1208 a and theright-midrange element 1208 b. In some embodiments, the focus point maybe adjusted by applying a uniform summing factor to the offsets betweenelements. The uniform summing factor may be applied to the offsetsassociated with substantially all the elements in the left-eye and theright-eye viewing frames. Additionally, in some embodiments, the uniformsumming factor may be applied to the offsets associated withcorresponding pixels of the left-eye and right-eye viewing frames.

FIG. 12D depicts an example grid 1205 that illustrates the offsets ofthe elements of FIG. 12B with respect to their respective left-eye andright-eye viewing frames after applying a uniform summing factor to theoffsets of FIG. 12B, according to some embodiments disclosed herein. Inthe illustrated embodiment, the uniform summing factor may be appliedsuch that the elements associated with the right-eye viewing frame areshifted to the left with respect to the elements associated with theleft-eye viewing frame. Such shifting to the left of the right-eyeviewing frame elements with respect to the left-eye viewing frameelements may result in moving the focus point back such that moreelements are perceived as being within the foreground.

In other embodiments, the uniform summing factor may be applied suchthat the elements associated with the right-eye viewing frame areshifted to the right with respect to the elements associated with theleft-eye viewing frame. Such shifting to the right of the right-eyeviewing frame elements with respect to the left-eye viewing frameelements may result in moving the focus point forward such that moreelements are perceived as being within the background.

In the illustrated embodiment, the uniform summing factor may have avalue of “−3” and may be applied to the offsets between the elements1206, 1208, and 1210 of FIG. 12B such that the right-eye viewing frameelements may each be shifted to the left by three grid units withrespect to their corresponding left-eye viewing frame elements. In theillustrated embodiment, a negative summing factor may result in a shiftto the left of the right-eye viewing frame elements with respect to theleft-eye viewing frame elements and a positive summing factor may resultin a shift to the right of the right-eye viewing frame elements withrespect to the left-eye viewing frame elements. However, in otherembodiments, a positive summing factor may result in a shift to the leftof the right-eye viewing frame elements with respect to the left-eyeviewing frame elements and a negative summing factor may result in ashift to the right of the right-eye viewing frame elements with respectto the left-eye viewing frame elements.

For example, in FIG. 12B a near element offset between the center of theleft-near element 1206 a and the center of the right-near element 1206 bmay be “2” grid units. Therefore, applying a summing factor of “−3” tothe near element offset illustrated in FIG. 12B may result in shiftingthe right-near element 1206 b “3” grid units to the left with respect tothe left-near element 1206 a such that the near offset between thecenter of the left-near element 1206 a and the center of the right-nearelement 1206 b may be “5” grid units after applying the summing factor,which is depicted in FIG. 12D.

Additionally, a midrange element offset between the left-midrangeelement 1208 a and the right-midrange element 1208 b may beapproximately “0” grid units. Therefore, applying a summing factor of“−3” to the midrange element offset illustrated in FIG. 12B may resultin shifting the right-midrange element 1208 b “3” grid units to the leftwith respect to the left-midrange element 1208 a such that the midrangeoffset between the center of the left-midrange element 1208 a and thecenter of the right-midrange element 1208 b may be “3” grid units afterapplying the summing factor, which is depicted in FIG. 12D.

Further, in FIG. 12B a far element offset between the center of theleft-far element 1210 a and the center of the right-far element 1210 bmay be “3” grid units. Therefore, applying a summing factor of “−3” tothe far element offset illustrated in FIG. 12B may result in shiftingthe right-far element 1210 b “3” grid units to the left with respect tothe left-near element 1210 a such that the far offset between the centerof the left-far element 1210 a and the center of the right-far element1210 b may be “0” grid units after applying the summing factor, which isdepicted in FIG. 12D.

In the illustrated embodiment, the right-near element 1206 b, theright-midrange element 1208 b, and the right-far element 1210 bassociated with the right-eye viewing frame may each be shifted to theleft by “3” grid units and the left-near element 1206 a, theleft-midrange element 1208 a, and the left-far element 1210 a associatedwith the left-eye viewing frame may not be shifted in FIG. 12D withrespect to FIG. 12B to obtain the desired amount of offset adjustment.In alternative embodiments, the near offset, the midrange offset, andthe far offset may be adjusted by shifting any one of the left-nearelement 1206 a, the right-near element 1206 b, the left-midrange element1208 a, the right-midrange element 1208 b, the left-far element 1210 a,and/or the right-far element 1210 b in FIG. 12D with respect to FIG.12B.

Additionally, the illustrated embodiment depicts shifting the elementsassociated with the right-eye viewing frame to the left with respect totheir corresponding elements in the left-eye viewing frame to move thefocus point back, which may bring more elements within the foreground asperceived by a viewer. However, as indicated above, in otherembodiments, the elements associated with the right-eye viewing framemay be shifted to the right with respect to their corresponding elementsin the left-eye viewing frame to move the focus point forward, which maybring more elements within the background as perceived by a viewer.

Accordingly, in accordance with some embodiments of the presentdisclosure, a stereoscopic video module (e.g., the stereoscopic videomodule 104) may be configured to adjust a focus point associated with astereoscopic video by applying a uniform summing factor to the offsetsbetween corresponding elements and/or pixels associated with theleft-eye viewing frames and the corresponding right-eye viewing framesof the stereoscopic video.

One skilled in the art will appreciate that, for this and otherprocesses and methods disclosed herein, the functions performed in theprocesses and methods may be implemented in differing order.Furthermore, the outlined steps and operations are only provided asexamples, and some of the steps and operations may be optional, combinedinto fewer steps and operations, or expanded into additional steps andoperations without detracting from the essence of the disclosedembodiments.

FIG. 13 is a flowchart of an example method 1300 of adjusting the depthof a stereoscopic video, according to some embodiments of the presentdisclosure. The method 1300 may be implemented, in some embodiments, bya stereoscopic video module, such as the stereoscopic video module 104of FIG. 1. For instance, the stereoscopic video module 104 may beconfigured to execute computer instructions to perform operations foradjusting depth of a stereoscopic video as represented by one or more ofthe blocks of the method 1300. Although illustrated as discrete blocks,various blocks may be divided into additional blocks, combined intofewer blocks, or eliminated, depending on the desired implementation.

Method 1300 may begin, and at block 1302 a left-eye viewing frame of astereoscopic video may be generated. The left-eye viewing frame mayinclude multiple left-eye viewing frame elements. In some embodiments,the left-eye viewing frame elements may be substantially all theelements included in the left-eye viewing frame such that the left-eyeviewing frame elements may encompass substantially the entire left-eyeviewing frame. Additionally, the left-eye viewing frame elements mayeach include one or more pixels.

At block 1304, a right-eye viewing frame of the stereoscopic video maybe generated. The right-eye viewing frame may correspond to the left-eyeviewing frame and may include a plurality of right-eye viewing frameelements. Each right-eye viewing frame element may correspond to one ofthe left-eye viewing frame elements. In some embodiments, the right-eyeviewing frame elements may be substantially all the elements included inthe right-eye viewing frame such that the right-eye viewing frameelements may encompass substantially the entire right-eye viewing frame.Additionally, the right-eye viewing frame elements may each include oneor more pixels.

At block 1306, an offset between each left-eye viewing frame element andits corresponding right-eye viewing frame element may be determined. Insome embodiments, the offset may be determined on a pixel-by-pixelbasis. At block 1308 a uniform multiplying factor may be applied to eachoffset such that a depth associated with the stereoscopic video may beadjusted on a substantially uniform scale.

Therefore, the method 1300 may be used to adjust the depth of astereoscopic video. One skilled in the art will appreciate that, forthis and other processes and methods disclosed herein, the functionsperformed in the processes and methods may be implemented in differingorder. Furthermore, the outlined steps and operations are only providedas examples, and some of the steps and operations may be optional,combined into fewer steps and operations, or expanded into additionalsteps and operations without detracting from the essence of thedisclosed embodiments.

For example, in some embodiments, the method 1300 may include stepsassociated with generating the left-eye viewing frame and the right-eyeviewing frame. In some of these embodiments, the left-eye viewing frameand the right-eye viewing frame may be generated according to one ormore manners described above with respect to FIGS. 1-11.

FIG. 14 is a flowchart of an example method 1400 of adjusting the focuspoint of a stereoscopic video, according to some embodiments of thepresent disclosure. The method 1400 may be implemented, in someembodiments, by a stereoscopic video module, such as the stereoscopicvideo module 104 of FIG. 1. For instance, the stereoscopic video module104 may be configured to execute computer instructions to performoperations for adjusting the focus point of a stereoscopic video asrepresented by one or more of the blocks of the method 1400. Althoughillustrated as discrete blocks, various blocks may be divided intoadditional blocks, combined into fewer blocks, or eliminated, dependingon the desired implementation.

Method 1400 may begin, and at block 1402 a left-eye viewing frame of astereoscopic video may be generated. The left-eye viewing frame mayinclude multiple left-eye viewing frame elements. In some embodiments,the left-eye viewing frame elements may be substantially all theelements included in the left-eye viewing frame such that the left-eyeviewing frame elements may encompass substantially the entire left-eyeviewing frame. Additionally, the left-eye viewing frame elements mayeach include one or more pixels.

At block 1404, a right-eye viewing frame of the stereoscopic video maybe generated. The right-eye viewing frame may correspond to the left-eyeviewing frame and may include a plurality of right-eye viewing frameelements. Each right-eye viewing frame element may correspond to one ofthe left-eye viewing frame elements. In some embodiments, the right-eyeviewing frame elements may be substantially all the elements included inthe right-eye viewing frame such that the right-eye viewing frameelements may encompass substantially the entire right-eye viewing frame.Additionally, the right-eye viewing frame elements may each include oneor more pixels.

At block 1406, an offset between each left-eye viewing frame element andits corresponding right-eye viewing frame element may be determined. Insome embodiments, the offset may be determined on a pixel-by-pixelbasis. At block 1408 a uniform summing factor may be applied to eachoffset. The uniform summing factor may be applied such that eachright-eye viewing frame element may uniformly shift by substantially thesame amount with respect to its corresponding left-eye viewing frameelement. The shifting may thus adjust a focus point associated with thestereoscopic video.

Therefore, the method 1400 may be used to adjust the focus point of astereoscopic video. One skilled in the art will appreciate that, forthis and other processes and methods disclosed herein, the functionsperformed in the processes and methods may be implemented in differingorder. Furthermore, the outlined steps and operations are only providedas examples, and some of the steps and operations may be optional,combined into fewer steps and operations, or expanded into additionalsteps and operations without detracting from the essence of thedisclosed embodiments.

For example, in some embodiments, the method 1400 may include stepsassociated with generating the left-eye viewing frame and the right-eyeviewing frame. In some of these embodiments, the left-eye viewing frameand the right-eye viewing frame may be generated according to one ormore manners described above with respect to FIGS. 1-11.

The embodiments described herein may include the use of a specialpurpose or general purpose computer, including various computer hardwareor software modules, as discussed in greater detail below.

Embodiments described herein may be implemented using computer-readablemedia for carrying or having computer-executable instructions or datastructures stored thereon. Such computer-readable media may be anyavailable media that may be accessed by a general purpose or specialpurpose computer. By way of example, and not limitation, suchcomputer-readable media may comprise tangible computer-readable storagemedia including RAM, ROM, EEPROM, CD-ROM or other optical disk storage,magnetic disk storage or other magnetic storage devices, or any otherstorage medium which may be used to carry or store desired program codein the form of computer-executable instructions or data structures andwhich may be accessed by a general purpose or special purpose computer.Combinations of the above may also be included within the scope ofcomputer-readable media.

The computer-executable instructions may be executed by a processingdevice and may include, for example, instructions and data that cause ageneral purpose computer, special purpose computer, or special purposeprocessing device to perform a certain function or group of functions.Although the subject matter has been described in language specific tostructural features and/or methodological acts, it is to be understoodthat the subject matter defined in the appended claims is notnecessarily limited to the specific features or acts described above.Rather, the specific features and acts described above are disclosed asexample forms of implementing the claims.

As used herein, the term “module” or “component” may refer to softwareobjects or routines that execute on the computing system. The differentcomponents, modules, engines, and services described herein may beimplemented as objects or processes that execute on the computing system(e.g., as separate threads). While the system and methods describedherein may be implemented in software, implementations in hardware or acombination of software and hardware are also possible and contemplated.In this description, a “computing entity” may be any computing system aspreviously defined herein, or any module or combination of modulatesrunning on a computing system.

All examples and conditional language recited herein are intended forpedagogical objects to aid the reader in understanding the invention andthe concepts contributed by the inventor to furthering the art, and areto be construed as being without limitation to such specifically recitedexamples and conditions. Although embodiments of the present inventionshave been described in detail, it should be understood that the variouschanges, substitutions, and alterations could be made hereto withoutdeparting from the spirit and scope of the invention.

What is claimed is:
 1. A method of adjusting a focus point in astereoscopic video, the method comprising: determining a horizontaloffset and a vertical offset of a first position of an element in afirst frame of a monoscopic video with respect to a second position ofthe element in a second frame of the monoscopic video; generating amodified first frame based on the horizontal offset of the element whileremoving the vertical offset of the element such that the element ishorizontally offset in the modified first frame as compared to the firstframe and such that the element is not vertically offset in the modifiedfirst frame as compared to the first frame; generating a first-eyeviewing frame of a stereoscopic video based on one or more of the firstframe and the modified first frame, the first-eye viewing frameincluding a plurality of left-eye viewing frame elements; generating asecond-eye viewing frame of the stereoscopic video based on one or moreof the first frame and the modified first frame, the second-eye viewingframe corresponding to the first-eye viewing frame and including aplurality of second-eye viewing frame elements, each second-eye viewingframe element corresponding to one of the first-eye viewing frameelements; and based on an offset between each second-eye viewing frameelement and its corresponding first-eye viewing frame element, shiftingeach second-eye viewing frame element with respect to its correspondingfirst-eye viewing frame element such that a perceived focus pointassociated with the stereoscopic video is adjusted.
 2. The method ofclaim 1, wherein: the plurality of first-eye viewing frame elementsencompass substantially all of the first-eye viewing frame; and theplurality of second-eye viewing frame elements encompass substantiallyall of the second-eye viewing frame.
 3. The method of claim 2, wherein:the plurality of first-eye viewing frame elements comprise first-eyeviewing frame pixels; and the plurality of second-eye viewing frameelements comprise second-eye viewing frame pixels.
 4. The method ofclaim 1, wherein shifting each second-eye viewing frame element withrespect to its corresponding first-eye viewing frame element comprisesshifting each second-eye viewing frame element, by substantially thesame amount, to the right with respect to its corresponding first-eyeviewing frame element.
 5. The method of claim 1, wherein shifting eachsecond-eye viewing frame element with respect to its correspondingfirst-eye viewing frame element comprises shifting each second-eyeviewing frame element, by substantially the same amount, to the leftwith respect to its corresponding first-eye viewing frame element. 6.The method of claim 1, further comprising: determining movement betweenthe first frame of the monoscopic video and a second frame of themonoscopic video; determining a camera effect based on the movement; andgenerating the first-eye viewing frame and the second-eye viewing framebased on the camera effect.
 7. The method of claim 6, wherein the cameraeffect comprises at least one of a panning effect, a zooming effect, arotating effect, and a stationary effect.
 8. The method of claim 6,further comprising: determining at least one of a foreground and abackground based on the first frame and the second frame; determiningmovement between the first frame and the second frame that is associatedwith at least one of the foreground and the background; and generatingthe first-eye viewing frame and the second-eye viewing frame based onthe movement associated with at least one of the foreground and thebackground.
 9. The method of claim 8, further comprising: determining atleast one of a fastest moving element, a slow moving element, and adominant element associated with the first frame and the second frame;and determining at least one of the foreground and the background basedon at least one of the fastest moving element, the slow moving element,and the dominant element associated with the first frame and the secondframe.
 10. The method of claim 6, wherein the second frame is asubsequent frame with respect to the first frame.
 11. The method ofclaim 6, wherein the second frame is a previous frame with respect tothe first frame.
 12. The method of claim 11, further comprising:detecting a scene change in the monoscopic video from a scene associatedwith the first frame and the second frame to another scene; inferring asubsequent frame of the scene associated with the first frame and thesecond frame in response to detecting the scene change and based on themovement between the first frame and the second frame; and generating atleast one of the first-eye viewing frame and the second-eye viewingframe based on the inferred subsequent frame.
 13. A non-transitorycomputer-readable storage medium, including computer-executableinstructions configured to cause a system to perform operations toadjust depth in a stereoscopic video, the operations comprising:determining a horizontal offset and a vertical offset of a firstposition of an element in a first frame of a monoscopic video withrespect to a second position of the element in a second frame of themonoscopic video; generating a modified first frame based on thehorizontal offset of the element while removing the vertical offset ofthe element such that the element is horizontally offset in the modifiedfirst frame as compared to the first frame and such that the element isnot vertically offset in the modified first frame as compared to thefirst frame; generating a first-eye viewing frame of a stereoscopicvideo based on one or more of the first frame and the modified firstframe, the first-eye viewing frame including a plurality of left-eyeviewing frame elements; generating a second-eye viewing frame of thestereoscopic video based on one or more of the first frame and themodified first frame, the second-eye viewing frame corresponding to thefirst-eye viewing frame and including a plurality of second-eye viewingframe elements, each second-eye viewing frame element corresponding toone of the first-eye viewing frame elements; and based on an offsetbetween each second-eye viewing frame element and its correspondingfirst-eye viewing frame element, shifting each second-eye viewing frameelement with respect to its corresponding first-eye viewing frameelement such that a perceived focus point associated with thestereoscopic video is adjusted.
 14. The non-transitory computer-readablestorage medium of claim 13, wherein: the plurality of first-eye viewingframe elements encompass substantially all of the first-eye viewingframe; and the plurality of second-eye viewing frame elements encompasssubstantially all of the second-eye viewing frame.
 15. Thenon-transitory computer-readable storage medium of claim 14, wherein:the plurality of first-eye viewing frame elements comprise first-eyeviewing frame pixels; and the plurality of second-eye viewing frameelements comprise second-eye viewing frame pixels.
 16. Thenon-transitory computer-readable storage medium of claim 13, whereinshifting each second-eye viewing frame element with respect to itscorresponding first-eye viewing frame element comprises shifting eachsecond-eye viewing frame element, by substantially the same amount, tothe right with respect to its corresponding first-eye viewing frameelement.
 17. The non-transitory computer-readable storage medium ofclaim 13, wherein shifting each second-eye viewing frame element withrespect to its corresponding first-eye viewing frame element comprisesshifting each second-eye viewing frame element, by substantially thesame amount, to the left with respect to its corresponding first-eyeviewing frame element.
 18. The non-transitory computer-readable storagemedium of claim 13, wherein the operations further comprise: determiningmovement between a first frame of a monoscopic video and a second frameof the monoscopic video; determining a camera effect based on themovement; and generating the first-eye viewing frame and the second-eyeviewing frame based on the camera effect.
 19. The non-transitorycomputer-readable storage medium of claim 18, wherein the operationsfurther comprise: determining at least one of a foreground and abackground based on the first frame and the second frame; determiningmovement between the first frame and the second frame that is associatedwith at least one of the foreground and the background; and generatingthe first-eye viewing frame and the second-eye viewing frame based onthe movement associated with at least one of the foreground and thebackground.
 20. The non-transitory computer-readable storage medium ofclaim 19, wherein the operations further comprise: determining at leastone of a fastest moving element, a slow moving element, and a dominantelement associated with the first frame and the second frame; anddetermining at least one of the foreground and the background based onat least one of the fastest moving element, the slow moving element, andthe dominant element associated with the first frame and the secondframe.